Printing mechanism for accounting



N V- 17, 1953 M. A. GOODBAR arm. I 2,659,391

PRINTING MECHANISM FOR ACCOUNTING MACHINES Original Filed July 17, 1948 9 Shets-Sheet 1 INVENTORS 'ERaH WBEfix: a CARL e. FALKNER BY j fin M THEIR ATTORNEYS N 7, 1953 M. A. GOQDBAR ETAL 2,659,301

NTN ME AN MFRAC MA Original Filed July 17, 1948 9 Sheets-Sheet 2 5 m @y g @@E@@ MAYO A N "a CARL .FA

IR ATT NNNNNNNN S 00D N v- 17. 1953 M. A. GOODBAR ET AL 2,659,301

PRINTING MECHANISM FOR ACCOUNTING MACHINES Original Filed July 17, 1948 9 Sheets-Sheet 3 l FIG. 3 I96 200 I95 [H |91./H[

' 1 J99 19a :97 I95 q I '8 5 T .H I 194* Lam -2o3 205 r203 1 207 i: r J I lfllv --|ao (Isl 492 I -|95 ISI} L ;'vlhl l l THEIR ATTORNEYS Nov. 17, 1953 M. A. GOODBAR ET AL 2,659,301

PRINTING MECHANISM FQR ACCOUNTING MACHINES Original Filed July 17, 1948 9 Sheets-Sheet 4 INVENTORS MAYO A. GOODBAR EVERETT H. PLACKE 8 CARL G. FALKNER THEIR ATTORNEYS 9 Sheets-Sheet 6.

Nov. 17, 1953 M. A. GOODBAR ETAL PRINTING MECHANISM FOR ACCOUNTING MACHINES Original Filed July 17, 1948 QON v '""%%B%'% A. g ET H. PLACKE 8 CARL G. FALKNER THEIR ATTORNEYS I Nov. 17, 1953 M. A. GOODBAR' ETAL PRINTING MECHANISM FOR ACCOUNTING MACHINES Original Filed July 1?, 194a 9 Sheets-Sheet 7 HEIR ATTORNEY$ nv oz Nov. 17, 1953 M. A. GOODBAR ET AL PRINTING MECHANISM FDR ACCOUNTING MACHINES 9 Sheets-Sheet 8 Original Filed Jul 17, 1948 0 0w. -oo m mwsvb v 398:2

Nth 2- 5:. mm QE gm BY THEIR ATTORNEYS Nov. 17, 1953 M. A. GOODBAR 'ETAL PRINTING MECHANISM FOR ACCOUNTING MACHINES y 17, 1948 9 smmm -m MMM M J m w m m I0 Patented Nov. 17, 1953 PRINTING MECHANISM FOR ACCOUNTING MACHINES Mayo A. Goodbar, Everett H. Placke, and Carl G.

Falkner, Dayton, National Cash Re Ohio, assignors to The gister Company,

Dayton,

Ohio, a corporation of Maryland Original application July 17, 1948, Serial No.

39,278, now Patent No. 2,616,623, dated Novem- Divided and this application May 13, 1950, Serial No. 161,838

8 Claims.

This invention relates to improvements in printing mechanism for accounting machines.

This application is a division of application Serial No. 39,278, filed July 17, 1948 (now Patent No. 2,616,623, issued November 4, 1952).

One object of the invention is to provide a machine for use in handling commercial accounts by a bank teller.

Another object of the invention is to provide novel printing mechanisms to record data necessary in making a complete record of transactions by a commercial bank teller.

A specific object of the invention is to provide a novel printer mechanism having removable units which can be taken out of the printer for storing records or for supplying record material therein.

Another specific object of the invention is to provide an automatic control over the operations of a printing hammer to cause the hammer to make one or two printing strokes.

With these and incidental objects in view, the invention includes certain novel features of construction and combinations of parts, a preferred form or embodiment of which is hereinafter described with reference to the drawings which accompany and form a part of this specification.

Of said drawings:

Fig. 1 is a perspective view of the machine, in

which the invention is applied.

Fig. 2 is a diagrammatic View of the keyboard,

Fig. 3 is a detail view showing the main framework of the machine as viewed from the front of the machine.

Fig. 4 is a sectional view taken at the right of the first transaction bank, showing the transaction difierentia]. mechanism and certain mechanisms adjusted thereby.

Fig. 5 is a detail view of the driving mechanism for the first transaction bank difierential mechanism.

Fig. 6 is a detail view of the beam-setting mechanism for the first transaction bank.

Fig. '7 is a detail view of certain parts of the first transaction bank differential mechanism.

Fig. 8 is a detail view of a part of the two cam lines of the machine.

Fig. 9 is a detail view of the clutch mechanism for starting the machine in operation.

Fig. 10 is a sectional view and shows the transaction bank differentials, together with the main cam line for operating the machine, looking from the front of the machine.

Fig. 11 is a sectional view taken just to the right of the second transaction bank and shows the second transaction bank differential mechanism and the connections for setting the type whee s and the control plates.

Fig. 12 is a cross-sectional view taken through the slip printer mechanism.

Fig. 13 is a detail view of a part of the slip feeler operating mechanism.

Fig. 14 is a detail view of printer control mechanism.

Fig. 15 is a detail view of a part of the slip feeler mechanism for controlling the slip printing and feeding mechanisms.

Fig. 16 is a detail view of the slip feeler and the actuating mechanism therefor.

Fig. 17 is a detail view of the control disc set under control of the second transaction bank of keys for controlling the operation of the printing hammer for the deposit slip printer.

Fig. 18 is a detail view of another control disc set under control of the second transaction bank of keys for controlling the operation of the printing hammer for the deposit slip printer,

Fig. 19 is a detail view showing the deposit slip printing hammer mechanism, together with the control disc set under control of the first transaction bank of keys, for controlling the hammer mechanism.

Fig. 20 is a detail view of a part of the mechanism shown in Fig. 19.

Fig. 21 is a top plan view of the control discs shown in Figs. 1'7, 18, and 19, together with the feeling fingers coacting therewith.

Fig. 22 is a facsimile of a deposit slip printed in the slip printing section of the machine.

Fig. 23 is a facsimile of a tellers cash ticket printed in the slip printing section of the machine.

Fig. 24 is a detail view showing one of the control discs set under control of the second bank of transaction keys for controlling the feed of the deposit slip.

Fig. 25 is a detail view of another notched disc set under control of the second bank of transaction keys Ior controlling the feed of the deposit slip.

a part of the slip Fig. 26 is a detail view showing the deposit slip feeding mechanism and a control disc set under control of the first bank of transaction keys for controlling the feeding mechanism.

Fig. 27 is a detail view showing a lock for the feed mechanism for the deposit slip.

Fig. 28 is a top plan view showing the deposit slip feeding rollers.

Fig. 29 is aside view showing the mechanism for controlling the deposit slip feed tensioning mechanism.

Fig. 30 is a detail view, shown in an enlarged scale, of the clutch mechanism .101 operating the deposit slip feed rollers.

GENERAL DESCRIPTION The invention illustrated herein is embodied in a. machine for use by commercial bank tellers. In handling commercial account transactions, it

is necessary to segregate deposits, in the iorm'oi checks, cash, and mixed checksand cash, from cash paid out transactions. 'In'recording these commercial bank transactions, it is also necessary to enter transactions wherein a check is presented, a part of the amount of which is deposited and the balance taken .in cash by the customer.

All the above transactions arerecorded .atthe tellerfs window in the present machine, which simultaneously produces printedrecords for .use by the Auditing and Bookkeeping Departments. Recording mechanisms are located at the front of the machine and include. a slip printer to print on deposit slipsand cash tickets, an audit tape printer, and an issuing tape printer.

The slip printer is located near the left .side of the machine just below .the keyboard and includes .a table upon which deposit slips or cash tickets are placed. When the total deposits shown by the deposit slip are entered into the totalizers of the machine, a total is .printedon the deposit slip. If duplicate deposit slips .are .to be used, the total is printed on each slip. In addition to the printing of the total of the deposit on the deposit slip, other .datais also set up on the printing member, suchas thedate, the bank number, the machine number, the consecutive number, and a symbol for the transaction. .An adjustable feed .is provided to permit easy control over the spacing of the double impressions to accommodate various printed forms. As illustrated herein, the distance between printed impressions can be varied from .6 inch to two inches in steps of 2 inch.

The automatic printing controlsover the slip printing hammer effected by eachkey of .the two transaction banks is briefly ta'bulated'below.

Deposit keys Depression of either deposit key, followed .by anoperation of the machine, will cause adouble impression to be .made on the deposit slip.

Deposit keys undrepeat key 1t theiRepeat key isdepressed in combination with a deposit key. the-machine, a single impression deposit slip.

"Cash In keys '01 Miscellaneous keys followed by an operation of is made on the 4 Cash Out" keys Depression of a Cash Out key, followed by an operation of the machine, causes the slip impression hammer to be disabled.

"Cash Out key with "List" key Depression of the List" key in combination with-a Cash Outv key, followed by an operation of the machine, causes theslip impression hammer to be disabled.

Balance key Depresslonot'the Balance key, followed b an operation of the machine, disables the slip print- .inghammer.

Balance key with Add Print key Depression of the Sub-Balance key, followed by an operation of the machine, causes the slip impressionhammer to be disabled.

Sub-Balance key mithndd Print Depression of .the.Add Print key in combination with the Sub-Balance .key, followed by an operation of the machine, causes the slip impression hammer to be disabled.

List key Depression of the List key, iollowedby'an ,operation of the machine, exercises no control over the slip impression hammer. Any control over the printing mechanisms which are effective during an operation of the machine with the List key depressed is effected by whatever key is depressed therewith. In the system described herein, it is contemplated that a Cash Out key be depressed in combination with the List key.

Add key The Add key controls the machine so that the amounts are added into the'List, or visible, totalizer, and all printing is disabled during the operation in which the Add key is depressed. Thus, when the machine is operated with the Add key only depressed, the machine operates as a straight adding machine.

Add key in combination with Repeat key Operation of the machine with the Repeat key depressed in combination with the Add key results .in the operation identical with that described for the Addkeyexcept that it repeats the addition of the-amount previously added.

Repeat key The Repeat keyis always used with a motorized key, and the controls eiTected depend on the controls of the key with which it is depressed, in themanner pointedout above.

Batch key TheBatch Reset key controls the machine to clear the batch totalizer corresponding to the key depressed, and the slip impression hammer is disabled.

.Batch Read key The Batch Read key controls the machine to operate exactly like the Batch Reset key, except that a. sub-total is taken and the selected totalizer is not cleared.

Reset key The Reset key controls the machine to reset any selected totalizer on the rear totalizer line, and the slip impression hammer is disabled.

Read key Operation of the machine with the Read key depressed results in the identical operation described with the Reset key depressed, except that a sub-total is taken and the selected totalizer is not cleared.

DETAILED DESCRIPTION Keyboard As shown in Figs. 1 and 2, the keyboard of the machine, as illustrated herein, is provided with eight rows of amount keys its and two banks of control, or transaction, keys It to H8 inclusive. The keys IEH to H8 inclusive are provided with legends to aid in their selection for controlling the machine in its operations. In addition to the controls indicated by the legends thereon, keys IGI to I98 inclusive, Iill, III, and H3 are what is known in the art as motor keys; that is, in addition to controlling the machine in accordance with the legends thereon, these keys also release the machine for operation. Keys I 29, I I2, and II 4 to H8 inclusive do not release the machine for operation, and therefore the must be depressed in combination with one of the motor keys. Near the lower right-hand corner of the keyboard is a release key H9, which is used to release the keys on the keyboard if for any reason it is desired to release them after they have been depressed and before the machine has been released for operation. The reset key II? is provided with a lock I20, whereby the teller may look the reset key during his absence. A similar lock I2I is provided for the read key I I8.

The amount keys its and the control keys IEiI to H3 inclusive are mounted in a frame which consists of a unit which may be removed from the machine in its entirety. This unit construction provides an economical and convenient production method, since the keyboard can be assembled separately and then assembled into the machine as a separate entity.

MAIN FRAMEWORK Fig. 3 illustrates the main frames of the machine. The left side frame HM and the right side frame I853 are mounted on a base 1% having lugs IilI thereon. Located intermediate the frames I St and 18f are a left printer frame it?! and a right printer frame I93 suitably secured to lugs on the base for]. Secured to the left side frame i8! is an auxiliary frame it, which is provided with two blocks m5. Secured to the right side frame its is an auxiliary frame I 95, provided with blocks i of. The blocks I Q5 and is? are tapped to receive screws projecting through a, back frame ass. Another auxiliary frame I 99 is provided with blocks 2% threaded to receive screws passing through the back frame see, by means of which the auxiliary frames liiii are supported on the back frame V88. A shouldered stud 262 (Fig. 11) is provided on each side of the printer frames I92 and W3, on one side of the left side frame I8i, and on one side of the right side frame Iliil. Near the front of the ma chine, a series of six auxiliary plates 2E3 (Figs. 3, 4, and 11) for supporting the type carrier and the setting mechanism are provided. Each auxiliary plate 203 has, on its lower rear end, a slot which is adapted to straddle the small diameter of a shouldered stud 202 when the type carrier unit, which unit is separately assembled, is inserted into the machine. A cross bar 2M is provided with a series of six notches, into which the upper edge of each plate 203, as best shown in Fig. 11, is inserted. After the type carrier unit has been separately assembled, in the manner described hereinafter, the entire unit is placed in the machine by inserting the notches of the auxiliary plates 203 over the small diameters of the shouldered studs 282, sliding the upper edges of the auxiliary plates 203 into the notches in the cross bar 2M, and inserting a shaft 204 (Fig. 11) through the right side frame I80, through all of the auxiliary plates 203, through the printer frames I32 and I93, and finally through the left side frame I8I. Near the rear of the machine, a cross bar in the shape of a. formed channel 206 (Figs. 3 and 11) is mounted between the side frames I and Isl The auxiliary frame I82 is formed at its rear end with a flatted surface, to which is Welded a threaded block to receive a screw 20'! to form a support for the auxiliary frame I 82. Near the rear of the machine, at its right, a bracket 2Iil (Fig. 4) is secured to the right side frame I80 by means of four screws EN. The bracket 2!!! is provided with a forwardly-extending ear 2I2 to support a cam shaft 2 I3, forming one of the main shafts for driving the mechanism of the machine. The bracket 2H) is also provided with a slot 2I4 for supporting the shaft 2 I 5 of an electric motor 2I6, which motor is one means for operating the machine. The motor 2I6 is carried by the cross bar 2 35 (Figs. 3 and 11).

MACHINE DRIVING MECHANISM The machine may be operated by an electric motor or by a hand crank. The motor shaft 215 (Fig. 4) has secured thereon a gear 220, which meshes with a gear 22I (Figs. 4, 8, and 9), loosely mounted on the cam shaft 2I3. Secured to the gear 22f is a clutch member with which a clutch pawl 223 engages when the machine isreleased for operation. The machine is released for operation by depression of a release key IN to I08, III), III, or H3. Depression of any one of these keys releases a shaft 946 to rock an arm 912 from a surface 910! of the clutch pawl 223, whereupon a spring 913 rocks the clutch pawl 223 into engagement with the clutch member 222. A stud 91 on a gear 224 normally maintains the pawl in disengaged position. The means for controlling the rocking movement of the shaft 941 is fully disclosed in the parent case. The clutch pawl 223 is pivotally mounted on the gear 224 secured to the shaft 2I3. The shaft 2I3 (Fig. 8) is supported at one end by the ear 2I2, on the motor bracket 2H3, and at the other end by a. bearing 225 in the right side frame I80. Also meshing with the gear 224 is a gear 226, secured to a sleeve 227, which is mounted to rotate on a cam shaft 229 and upon which are mounted two pairs of cams 123 for operating the first and second transaction differential mechanisms. Also secured on the sleeve 22! is a clutch member 228 (see Figs. 3 and 9), which is controlled to operate the cam shaft 229 selectively in accordance with certain types of operation of the machine. The shaft 229 also has fast thereon a gear 230 (Fig. 8). The gear 230 meshes with a gear 23I mounted on a sleeve 233, mounted to rotate on a stud 232 carried by the right side frame I 80. The gear 23I meshes with an intermediate gear 819, which also meshes with a gear I214 secured smear 7 tothe printer operating cam shaft I212 (Fig. 12).

If desired, the machine may be operated by a hand crank, which is slidably mounted on a stud 24!: (PE. 8) on the right side frame I80. when it'is desired to operate the machine by the hand crank, the. handle is slid endwise on the stud 2 to engage it with a hub 242, also rotatably mounted on the stud 24I. Secured to the hub 242 is: gear 244, meshing with an intermediate pinion 24!, rotatably mounted on a stud 246 on the right side frame I80. Meshing with the pinion 200 is a gear 243 rotatably mounted on a stud 24! supported in the right side frame I00. Meshing with the gear 243 is a gear 240 secured to the end of a shaft 249 rotatably mounted in a bearing 250 carried by the right side frame I00. Also on the shaft 249. is a gear 25I (Figs. 4 and 8) meshing with the beforementioned gear 220 (see also Fig. 9).

Rotation of the hand crank, through the train of gears 244, 245, 243, and 248, the shaft 240, and the gear 25I, rotates the gear 226 in the same manner as described in the description of these connections as driven by the motor shaft 2I5. In a hand operation, the clutch pawl 223 ratchets idly over the ratchet teeth of the clutch mem' bar 222.

AMOUNT KEY BANKS Each bank of amount keys includes a full complement of nine keys I (Fig. 1), and each bank of amount keys controls the setting of digits on type wheels at the printing line through connections including a shaft 504 (Fig. 11). The said connections are fully described in the abovementioned parent case.

TRANSACTION KEYS The transaction keys for controlling the various functions of the machine are arranged in two banks, as shown in Fig. 2. inclusive control the selection of totalizers into which amounts are to be added, as fully explained in the above-mentioned parent case, in addition to controlling certain operations in the printer section of the machine in hereinafter. This bank of keys will be referred to herein as the second transaction bank.

The keys IIO to H0 inclusive control the time and the manner of operation of the totalizer engaging and disengaging mechanism, as fully explained in the above-mentioned parent case, together with controlling certain functions of the printing mechanism described hereinafter. The bank of keys IIII to H0 will be hereinafter referred to as the first transaction bank.

TRANSACTION BANK DIFFERENTIAL MECHANISMS The depressed keys in the first and second transaction banks control the differential movement of actuators which control the various functions of the machine. Inasmuch as both differential mechanisms are alike, only one will be described herein in detail. Figs. 3 to '1 inclusive and will be referred to in the description of the transaction bank differential mechanism. Figs. 3 to 'r inclusive illustrate the differential mechanism for the first transaction bank.

First transaction bank difierential mechanism Coacting with studs 510 of the keys IIO to H8 inclusive is a differentially settable slide 00! (Figs. 4, 7, and 10). The studs 519 on the transaction keys alternately project to the right and left (Fig. 10) into the path of alternately-arranged The keys IN to I08 the manner described cars 690 formed on the slide 089. The relationship between the studs 510 and the ears 690 is such that, on operation of the machine with a key depressed, the slide 000 is arrested in a position commensurate with the position of the depressed key. The slide 080 is slotted at its front and rear ends to be supported by, and slide on, collars 69I and 602 carried by studs 692 and 604, respectively. The studs 000 and 604 are riveted on the frame I02 (Fig. 10) and are provided with tenons projecting into the side frame I00, and a screw 695, entering a tapped hole in each stud 600 and 604, maintains the frame I00 in proper relationship with the studs 693 and 694. Suitable spacing collars are provided to properly space the slide 000 on the studs 00: and 094, as clearly shown in Fig. 10.

The slide 689 is provided with teeth 896 (Fig. '1) meshing with a segment 691 of an arm 608 having a slot 699, into which projects a stud of a latch 10I (Figs. 5 and 6). The arm 090 is rotatably mounted on a stud 102 carried by the frame I82 and by the side frame I00. The latch 10I is pivotally mounted on a stud 103 carried by an arm 104 also pivotally supported on the stud 102. A beam 105 is pivotally mounted on the arm 104 by a stud 105. The free end of the beam 105 is provided with a stud 101, which projects into a slot 108 of an arm 108, also pivoted on the stud 102. The arm 109 is provided with a segment 1I0, meshing with teeth 1II (Fig. 4) of a type setting control slide H2. The control slide H2 is slidably mounted on the aforesaid collars Gill and 692, and at its upper end by a stud 688 mounted between the frames I50 and I99 (Fi 3).

The latch 10I (Figs. 5 and 6) is provided with a toe 1I3 normally engaging with a notch III of a differential driver H6. The differential driver I I6 is pivoted on the stud 10-2 and is provided with a notch 1I1, into which projects a stud IIS on the free end of a lever H9 pivoted on a stud carried by the frames I80 and I02. The lever H9 is secured to an arm 133 (Fig. 4) by a hub 12I. The arm 133 is provided with a pair of rollers 122, which coact with the pair of cam plates 123 (Figs. 4 and 10) secured to, so as to be rotatable by, the aforementioned sleeve 221 (Figs. 8, 9, and 10). The lever 1I0 (Figs. 5 and 6) is provided with a roller 124, which is movable into engagement with a surface 125 of the beam 105 in a manner to be described presently.

When the cam plates 123 are rotated. upon rotation of the sleeve 221, the arm 133 is rocked clockwise (Fig. 4) to rock the lever 1I3 clockwise. Clockwise movement of the lever 1 I 8, through the stud 1 I0 and the notch 1 I I, rocks the differential driver 1I5 also clockwise. Clockwise movement of the driver 1I6 carries with it the latch 1M and, through the stud 100, rocks the arm 690 (Fig. '1) clockwise. Clockwise movement of the arm 698, by the segment 681, moves the slide 680 to the right (Fig. 4) until one of the ears 090 thereon comes into contact with the stud 519 of a depressed key. This arrests the slide 609 in a position commensurate with the depressed key and at the same time positions the arm 690 (Fig. '1) in a corresponding position. Arresting of the arm 698, through its cam slot 699 acting on the stud 100, cams the latch 10I counter-clockwise around its stud 103, thus withdrawing the toe 1I3 from the notch 1I5 to arrest further movement of the arm 104. Counter-clockwise movement of the latch 10I (Fig. 6) cams an car 120 thereon into a corresponding notch 121 (Fig. 4.

of a locking plate 728 supported by the studs 693 and 728-. Continued movement of the driver He, after the latch 7'3! has been disengaged therefrom, moves a concentric surface 729 (Fig. thereof beneath the toe locks the latch 76! and the arm let in adjusted position, with the result that the stud 1'86 for the beam is also looked in an adjusted position corresponding to the depressed key.

During the clockwise rocking movement of the lever H9, the roller 72 i thereon comes into engagement with the surface 725 of the beam and rocks the beam 7% around the stud its as a center. Movement of the beam 5 35 around the stud 766 cams the stud it? on the lower end thereof into the slot 763 and'rocks the arm and the segment 776 into a position corresponding to the position in which the arm its has been adjusted and locked by the latch 764. This adjustment of the segment 7553, through the teeth 7H on the slide 712, positions the slide 752 cor responding to the adjusted position of the differential slide 689.

After the control slide 7l2 has been positioned by the beam 795 in the manner just described, the cams 523 return the levers 715i counter-clockwise to restore the differential driver He into its home position. During this counter-clockwise movement of the driver 776, when the notch H5 again comes beneath the toe M3, the toe 713 drops behind the notch H5, and, upon continued clockwise movement, the driver 756, acting through a roller 7! 4 thereon, engages the arm its and restores the arm 76% and the latch Hill to their home positions. During this movement, the segment Ill! and the control slide H2 are held in their adjusted positions by means described hereinafter, and therefore the beam 795 pivots around the stud 707. The segment no remains in the adjusted position until readjusted during the next succeeding cycle of operation.

A counterbalancing plate 73!) (Fig. '7) is pivotally mounted on the stud 7G2 adjacent the slide 698 and has a slot 73!, through which the stud Hill on the latch 70! projects. A spring 732. stretched between the counterbalancing plate i353 and the arm 5%, normally maintains the parts in the positions shown in Fig. '7. If, during the operation of the machine, the latch 734 has a tendency to withdraw prematurely from the notch H5 due to centrifugal force, the plate 736 prevents such movement. When the arm $98 is positively arrested, upon an ear 69!! on the slide see coming into contact with the stud 579 of a depressed key, the stud rec, operating in the cam slot 699, rocks the latch 76! counter-clockwise in the manner described above. Counterclockwise movement of the latch 75! moves the stud 78c thereon in the cam slot 73! to rock the counterbalancing plate its clockwise against the action of the spring 732. Since it is necessary to stretch the spring 732 to move the stud 7st in the cam slot 699, the spring 732 and the plate rec act to prevent premature disengagement of the latch 70] from its driver H6.

Second transaction bank differential mechanism The differential mechanism for the second transaction bank is identical with the differential mechanism just described for the first transaction bank, and, therefore, the same reference numerals are applied in Fig. 11. The description of the first transaction bank differential mechanism applies to the second transaction bank difierential mechanism.

H3 and positively Two type wheels 735 (Fig. 4) are provided to print symbols on the audit tape, and on the issuing strip (not shown herein), indicating the kind of operation being performed. The control slide 7l2 controls the positioning of the type wheels 735 mounted on the shafts sea in the audit tape printing section and in the issuing strip printing section. No type wheel 735 is provided in the slip printing section.

Formed on the underneath side of the control slide 772 are teeth 736 (Fig. 4), which mesh with a segment 73'! rotatable on a shaft 498. Connected to the segment 737 by a hub 738 is a segment 739, which meshes with a ring gear 740 on a disc Mi by a shaft 632. A pinion 742 meshes with the inner teeth of the ring gear 740 and is mounted on a square shaft 743 extending between the side frames I86 and I3! Also connected to the square shaft 743, so as to be driven by the first transaction bank differential mechanism, are a series of control discs for controlling the printing operations, in a manner described hereinafter.

Second transaction bank type wheel setting mechanism The control slide 7|2 (Fig. 11) for the second transaction bank controls the setting of a symbolprinting type element 755 in each of the three groups of type elements. The symbol-printing type wheel 755, in each group of type wheels, lies adjacent the highest amount type wheel.

Formed on the under side of the control slide 7I2 (Fig. 11) are a series of teeth 756, meshing with a pinion 757, which is connected to a segment 758 by a sleeve 759. The segment 758 meshes with a ring gear 760 carried by a disc 76! mounted on the shaft 632. The ring gear 760 has inner teeth meshing with a pinion 762 carried by a square shaft 763. Also carried by the square shaft 763 are pinions, similar to the pinion 762, adjacent each one of the three ring gears 764, one being provided for each group of type wheels. Meshing with each ring gear 764 is an intermediate pinion 765 on the shaft 524. Meshing with each intermediate pinion 765 on the shaft 524 is a ring gear 766, meshing with the respective type wheels 755. Through the connections just described, the setting of the control slide 772 adjusts the type carrier 755 into a position corresponding to the position to which the control slide 7| 2 is adjusted by the differential mechanism under the control of the depressed keys l0| to MB of the second transaction bank to set a symbol at the printing line to identify the key which was depressed, and, through connections later described, sets certain control discs for controlling the operation of the printing mechanism in the slip printer.

Insertable slip printer In the herein-illustrated system for a commercial bank teller, the machine is adapted to slips, such as a deposit slip (Fig. 22) and a tellers cash ticket (Fig. 23). The data to be printed includes the date, the bank number, the machine number, a consecutive number, a symbol for the teller, a symbol representing the kind of entry, and the amount of the deposit. The printing mechanism for printing on the in- 11 sertable slip is located at the lower left-hand corner of the machine, as viewed in Fig. 1.

In commercial accounts, the deposit being made by the customer may consist of all checks, all cash, or mixed deposits including both checks and cash. In order to assist the Auditing Department to audit the tellers cash balance, it is usually the practice for the teller to fill in a cash ticket, indicating the amount of cash taken in on any deposit, whether it is a straight cash deposit or a mixed cash and checks deposit. When a deposit including both checks and cash is made, the machine disclosed herein prints the total of the deposit on the deposit slip and the amount of cash included in the deposit on the cash ticket. One copy of the deposit slip and the cash ticket are sent to the Auditing Department with the checks. In auditing the individual transaction, the auditor first enters the total amount of the deposit on a bank proof machine and then subtracts the amount read from the cash ticket, then the amount of each check involved in the particular deposit. If the transaction is complete in all respects, the bank proof machine indicates a clear balance.

The deposit slip is prepared in duplicate, so that the teller can give one copy to the customer and send the other copy to the Auditing Department. The deposit slip also rovides means for properly crediting the customers account with the total amount thereof, after it is properly proved out in the bank proof machine.

In addition to proving the correctness of the entries of the items on the deposit slip, the tellers cash ticket also provides a means for balancing the cash in a tellers cage. At the end of the days business, the auditor totals all of the cash tickets for a given teller, which gives him a total of the amount of cash taken in by the teller. The audit strip, to .be described presently, furnishes a total of the amount of cash which the teller pays out. The difference between the amount of cash taken in and the amount of cash paid out gives the auditor the balance which the teller should have in his cage.

As illustrated herein, the miscellaneous keys in the second transaction bank also control a slip impression means to make one impression on an insertable slip. The form of slip used for this purpose depends upon the nature of the use to which the miscellaneous key is put.

Insertable slip printing mechanism The deposit slip I24I (Fig. 22) or the cash ticket I242 (Fig. 23) is positioned on a slip table I243 (Figs. 1 and 12) supported on the frames I8I and I92 (Fig. 4). Guide lines I244 (Fig. 1) are engraved on the slip table to guide the teller in positioning the slip on the slip table I243 in the proper relationship with the printing wheels in the slip printing section. All of the slip printing mechanism is located between the frames I8I and I92 (Fig. 3), and the slip table I243 is provided with an opening I245, through which a printing hammer I245 is moved to carry the inserted slip I24I or the cash ticket I242 and a ribbon I241 against the type wheels to make an impression. The printing hammer I246 is carried by a support I240 (Fig. 19) guided on a stud I249 carried by the frame I92 and a similar stud I249 carried by the frame I8I. Each end of the supporting member I249 is provided with a stud I250, which projects into a notch I25I formed in each of the side frames I8I and I92.

The studs I249 and I250, therefore, provide a means for guiding the printing platen in its vertical or up-and-down printing movements.

Mounted on each end of the supporting member I248 is a stud I252 (Fig. 19), which are engaged by the bifurcated ends of bell cranks I253 secured to a shaft I254 pivotally supported in the frames I8I and I92. Connected to the bell, crank I253, adjacent the frame I92, is a link I255, the right-hand end of which is slotted to engage over a stud I256 to guide the link I255 in its movements. A spring I251, connected to the link I255 and a suitable stud on the frame I92, normally maintains the hammer in its lower position, the stud I256 acting as a stop for the link I255 when held in its normal position, shown in Fig. 19. The right-hand end I258 of the link I255 is offset into the plane of a stud I259, which acts as a pivot between an arm I260 and a toggle link I26l. The stud I259 is shouldered to provide space between the link I26I and the arm I260, into which space the end I258 of the link projects. The arm I260 is mounted on a stud I262, carried by the frame I92. A stud I263 on the frame I32 acts as a limiting stop for the arm I269. A second toggle link I264 is connected to the toggle link I26I by a stud I265, and the opposite end of the toggle link I264 is pivoted to an arm i256, pivoted on a stud I261 carried by the frame I92. A stud I269 on the frame I92 acts as a limiting stop for the arm I266 when in its home position. The stud I255 projects laterally fro ii the link I264 and into a bifurcated end of a cam arm I259, pivoted on a shaft I325 carried by the frames IBI, I92, I93, and I80.

The cam arm I269 is provided with two antiiriction rollers I21I, which are acted upon by a pair; of cams I212 secured on the printer shaft The printer cam shaft I213 is rotated from the main cam shaft 229 (Fig. 8) by the train of gears including the gears 230, 23I, and 819, above mentioned. Meshing with the gear 819 is the gear I214, secured to the printer cam shaft I213. The ratio of the train of gears 230, 23I, 819, and I214 is such that one complete rotation of the main cam shaft 229 rotates the printer cam shaft I213 one complete rotation.

Counter-clockwise rotation of the cams I212 rocks the cam arm I269 first clockwise and then counter-clockwise, back to its home position. (Ilockwise movement of the cam arm I259, actmg on the toggle stud I255, tends to straighten the toggle composed of links I26I and I264. If the arm I266 is held against clockwise rotation. the toggle is straightened and the arm I260 is rocked counter-clockwise. Counter-clockwise movement of the arm I260 moves the link I255 toward the left (Fig. 19) to rock the bell cranks I253 clockwise, which, through the studs I252, raises the printing hammer I246 to take an implression from the type wheels onto the inserted s m.

The extent of rocking movement of the arm I269 is such that the toggle links I26I and I264 are moved into a horizontal position and beyond to again break the toggle joint. Therefore, when the arm I269 is restored in a counter-clockwise direction, the toggle links I20I and I264 are straightened before they are broken, upon their return to their normal position. This movement is taken advantage of in controlling the printing hammer for making one or two impressions. The first impression is made when the toggle is straightened during the clockwise movement of 13 the cam arm I 269, and the second impression is made when the cam arm 269 is returned counter-clockwise to it home position.

Whether the platen is operated to make one impression, two impressions, or no impression at all depends upon whether or not the arm I266 is blocked against clockwise movement. The blocking of the arm I266 is eifected by a seg ment i215, pivoted on a shaft i2i6, carried by the frames 56! and I 92. If the segment I275 is rocked counter-clockwise before the cam arm I269 is rocked clockwise, the segment i275 moves under a stud I240 on the arm I266. If the segment I275 is held under the stud I246 during both the clockwise and counter-clockwise movements of the cam arm I269, two impressions will be made. If only one impression is to be made, the segment I228 is withdrawn from beneath the stud I296 prior to the counter-clockwise return movement of the cam arm I269. If, on the other hand, no impression at all is to be made during the machine operation, the segment I225 is controlled to remain in the position shown in Fig. 19, and therefore no impression will be made during either the clockwise movement or the counter-clockwise movement of the cam arm I269.

The selective movement of the segment I215 is controlled by notched discs I 27? (Fig. 1'7) and I216 (Fig. 19). The notched disc I217 is adjusted under control of the secondtransaction bank through the square shaft 768, which shaft is rotated in a manner hereinbefore described for the setting of the type carriers 255. The notched disc I211 is mounted on a disc I279 and is provided with internal teeth meshing with a pinion on the square shaft and the disc I219 is mounted on the shaft 662.

The notched disc I 218 is provided with internal teeth mounted on a disc I280, carried by the shaft 632, and said internal teeth mesh with a pinion on the square shaft 743, which shaft, as hereinbefore described, is adjusted under control of the first transaction bank of keys.

The discs I211 and I278 are provided with notches, some of which are deeper than others. Coacting with the periphery of the notche discs I211 and I278 is a feeler mechanism comprising a finger I 28I in the plane of the disc I 211, carried by an adjustable block I285, rotatably mounted on a stud I282, carried by a feeler link I283. The feeler link I283 is provided witha finger I284 in the plane of the disc I218. The block I285 is rotatable on the stud I282 to vary the control over the printing hammers in a manner to be described hereinafter. A spring plate I286, carried on studs I281 on the link I 283, provides a means for maintaining the block I285 in its adjusted position.

The link I 283 is slotted to slide on a stud I288 at its left end and is pivoted on an arm I289 at its right-hand end. Th arm I289 is pivotally mounted on a shaft I290, and a rearwardly-extending arm I 29I ofthe arm I289 has pivoted thereto a link I 292, the lower end of which is pivoted to the segment I215. A spring I293, one end of which is connected to the stud I288, and the other end of which is connected tothe pivot stud on the arm I 289, maintains the arm I289, the link I292, and the segment I275 in their normal ineffective positions. In the normal position of the arm I29I, a stud I294 thereon rests on a shoulder of an arm I 295, secured to the shaft I290. Also secured to the shaft I290 is a cam arm I296 (see also Fig. 26). The cam arm I296 is'provided with an anti-friction roller I291,normally held against a cam I298 on the main cam shaft 229 by a spring I 299 (Fig. 26), acting through a yoke I423 and a stud I425, described later. I 1

1 When, during the operation of the main cam shaft229, the outer periphery ofthe cam I298 moves. beyond the roller I 291, the spring I299 rocks the arm I 296 clockwise to rockthe shaft I290 and to thereby lower, the arm I295 (Figs. 19 and 20), thus permitting the spring I293 to move the. arm I29I andthe link I292, together with the segment I 215, to move the latter be-v neath the stud I240, if permitted to do so by notches'in the discs I211 and I278. a

If, when the arm I29I starts to rock clockwise undercontrol ofthe cam I 298, the fingersI284 and I29-I1 contact the outer periphery of the control discs I211 or I218, the feeler link is immediately arrested, thus preventing the arm I29I from moving clockwise, thereby holding the link I292 in its normal position to thereby prevent the seg ment I 215 from moving beneath the-stud I 240. Under this condition, no impression is made when the cam arm I269 later moves the stud I265. The resistance met by the stud I259, due to the spring I251 and the weight of the parts, including the link I255, the bell crank I253, and the hammer I246, prevents the arm I260 from rocking counter clockwise. This causes the arm I266 to rock clockwise, and therefore the link I255 is not moved to operate the printing hammer.

If, when the arm I29I is released under con trcl of the cam I298, both fingers I28I and I284 enter notches in the discs I211 and I218, respectively, the arm I29I is free to rock clockwise, thus lowering the link I292 and moving the segment I275 counter-clockwise beneath the stud I240. Thereafter, upon rocking movement of the arm I299, the arm I266 is maintained against clockwise rotation, and therefore the toggle consisting of the links I26I and I264 is straightened to rock the arm I260 to shift the link I255 and the bell crank I253 to raise the printing hammer I246 to make an impression.

If the fingers I28I and I284 enter deep notches such as those shown in positions 4 and 8 of the notched disc I 211 and in position 10 in the disc I278, means presently described controls the segment I215 to remain under the stud I240 during both the clockwise movement and the counterclockwise movement of the cam arm I269, and therefore two impressions are made, one during the clockwise movement of the arm I269 and the other during its counter-clockwise movement.

After the two impressions have been made,

the cam I 298, ooacting with the roller I 291, restores the cam arm I296, the shaft I290, and the arm I295 counter-clockwise to their home positions. During this movement, the arm I295, engaging the stud I 294, restores the arm I29I, the link I292, and the home positions. I

In operations of the machine when the fingers I28I and I 284 enter the shallow notches of the discs I277 and I218, respectively, or when one of the fingers I28I or I284 enters a deep notch and the other enters a shallow notch, the feeler link I283 and therefore the arm I29I are not moved as great an extent as when these fingers both enter deep notches. When this condition exists and the cam arm I296 is rocked clockwise to rock the arm I295 likewise, the arm I29I and the link I292 are moved an extent less than when both fingers enter deep notches. Upon segment I 215 to their continued movement fthe-arml205; other the link 1202 is arrested, a surface I30.0 ot' thearm I205 (Fig. 20) ismoved beyond a stud I30I of a pawl I302 pivotally mounted on a, stud I303, which forms a pivot point between the arm I20I and the-link I202. A' spring I304, stretched between the stud I30I and the-"stud I204, normally tendstorock the pawl I302 clockwise. Therefore. when the surface I300 moves beyond the stud. I30I, thezspring I304 rocks thepawl I302 clockwise; tofoliow the inclined surface I305 or the-.arm I205. This clockwise movement of the pawl. I302 positionsitsend I305 into'the path of azflnger I3II of'a'cam arm I350, pivoted on the shaft I200, the latterhaving a roller I340 held inanmement with a cam I340 (Figs. 19- and 20), 011-; the; main cam shaft-220, by-a spring I352; men-m I348 permitsrthearm I350 to-rock first clockwise .under the influence of the spring I352 (1531:;20) andthenbackto homeposition. when thecarn I340 restores-thecam arm- I350. to its homoposition, the finger I35I engages the end I305. ot thepawl I302 and moves the pawl I302, together with the link I202, upwardly. This movement takes place prior to the time the cam I200 receives. its counter-clockwis move-- ment. and. therefore, when the link I202 is moved upwardly by the finger I35I, the segment I215 iawithdrawnfrombeneath the stud I240. Thereioretbe second impression does not take place.

When-.the feelingfingers I28] and I204 enter the deep notches; thelink 1202 partakes of the entireunQl ementof. the arm I205, and therefore the surface'.I300isineyer withdrawn from con- 250 3 with. the stud I30I, and theend I308-of=the I302 remains;.out,ofthe path of the finger I 3 5I. nuring the restoring movement of the arm I350, thefingerv I351 does. not contact theend I305 Qf thegpawl I302, and: therefore thelink I202 is;restored toitshome position after the second impressionzhasbeen. made; in. the manner descr d a ov As shown' in Figs..l'7-and 19, the discs I21] and I218 are notched,, so that. it. a, Deposit key is depressed in the second transaction bank: and no key is depressed in;the first transaction bank, a deep notch is positiqncd in the path: ofr'thefinger I.20 I,, as shown byjpositionsz i and 810i Fi 1'1 and. position 10 ofFig. 19. andtherefore, on any deposit entryin the machine-.;.twoimpressions are madetoprint .11.. the. duplicate; deposit slips. If, one of the, miscellaneousgkeysor; one ofv the 088 1 1 .keys pr s ed. in the; second transaction and, no key is depressed, in.- .the: first transaction bank one'of the shallow notches of positionsi, 3, 5, or 7 is positionedin the path of the finger IZBI, and a, deepnotch is'in the-position of. the-finger I284, and therefore only-one impression will be made. If. arepeatkeyin-position of the first transaction bank is depressed, the shallow notch shown; in position. 5 (Fig. 19) is. presentedto the finger I284, and a,-notchy con responding to whichever key is depressedinthe second bank willbe positoned in the-path of the finger. I20I. In thisoperatiomthe shallow. notch in position 5.0f thedisc; I218 controls the printing mechanism to make one; impression.- Thereiore, one all repeat operationsonly one impression is made by theprinting hammer, even thougha. deep notch may be presented to. the finger I28I. This is so because, a shallow; notch always takes. precedence inits 0011191101; over: a, deep notch presented to the fin er, I20I. or I284.

The adjustable block I285.is provided so that, it the system bein sed. requires. a. different printing control, such different printing control can be obtained by simply rotating a block I235 on the stud I282 tomove the finger I20I out of effective position with respect to the disc I211 and moving a finger I308 on the block I205 to efiect a position in respect to a third disc I300 (Fig. 18). As illustrated in Fig. 18, all of the notches shown are deep notches. That is to say, a deep notch is provided in each of the positions 1, 3, 4, 5, '7, and 8. Under this adjustment of the block I205; the finger I300, always engaginga deep notch, will causetwo impressions-to be made during every printing operation when no key is depressed in the first transaction bank, whereby a deep notch is also presented to the finger I204. With the block I205 moved to theposition to be controlled by the disc I300 and a Repeat key dopressed in the first transaction bank, a shallow notch in position 5 is moved into the path of a finger I234, and therefore only one impression will be made even though a deep notch is presented to the finger I300 in the manner described above.

The. novel arrangement. whereby the feeling finger I28I or I300 can be manually adjusted, to be controlled by their respective notched discs, forms a simple and effective way of changing the printing control whenever it is desired to change the control over the printing hammer. It is to be understood that the notching of the discs as shown in Figs. 17., 18;,and 10are only examples for controlling the printing hammer to fit the particular system described herein;v These discs may be notched in any desired manner so that the printing control may be effected to fitany system in which themachine is to be used.

Slip 'jeelina mechanism A slip feeling mechanism is provided in the machineso as to disable the- .printinehflmmer if no slip.v is placed on the sliptable. I243 (Fig, 16), to prevent idle operation of. the printing hammer. and preventv smud ing the.-printing platen.

The slip. feeling. mechanism includcsa. ieeler I3I5 (Figs. 12 and,16),which,is-arranged to enter an opening. I316 of the slip table, I243 to feel. for the presenceof a slip... If no slipis-on the table and. the machine .isv operated, the; slip feeler I3" is raised to therebyprescnt. an. obstructionin the path of the link I202 .(Figs. 15 and 19). to prevent thesegment I215 fromzmovins beneath the stud, I240; sothat the-toggle links. I20I: and I264 willnotactuate the. arm.i20 0,the I255, and the hammer I245.

' The .feeler I31I5 (Fig, 16) isguidedinitsupward and downward movements by the beforementioned shaft I254 and a shaft I3I'I, carried by the frames IOI and, I02. The lower end of the slip feeler I3I5 is pivoted toa bell, crank I3I3. securedon a shaft I3I0, carried by the frames I8I and. I02. The lower arm of the bell crank I313 has connected thereto. a spring I320, the other end of which is secured to astud I32I on theframe I02; Also securedonthe shaft I310 is anarm, I322; to which is pivoteda link. I323 at one end, the other end of the linkbeingconnected to an arm. I324 pivoted on the shaft I320 (see also Fig. 13) carriedby theframe I30, IOI, I02, and I03. The arm..I324 isprovided. with a finger I326, which is normally held against, a flange I321 (Fig. 16) of a pawl I328,;pivoted on a stud I320. of a. cam followenarm I330, by the spring I320 Thefiange I321, therefore, provides a. means forilocating thedeeler finger I3I5 in respent to-vthesliprtableiflt The cam arm I330 is pivoted on the shaft I325 and is provided with an anti-friction roller I63I, held in engagement with a cam I332 on the printer cam shaft I213 by a spring I333 stretched between a stud on the arm i336 and a stud on a segment I334 secured to the shaft I216.

Also secured to the shaft I216 is a segment i335 (Fig. located in respect to a flange 5336 on the link I232, so that, upon the segment 5335 being rocked counterclockwise, the segment moves beneath the flange I336 and prevents downward movement of the link I292. The segment I334 is integral with an arm I331 (Fig. 14), the arm I33? being provided with a stud I336,

which projects into a notch in an arm i339, pivotally mounted on the shaft I325. The arm 333 is integral with a segment I343, the outer periphery 3st of which is slightly lower than the periphery I362 of the arm I324 (Fig. 13).

When the printer can shaft I213 is rotated counter-clockwise (Fig. 16), the spring I333 rocks the cam arm I333 counter-clockwise to carry the pawl i326 and its flange I 321 away from the finger 5326 of the arm I 324. Movement of the flange I321 away from the finger I326 releases the arm i324 and the link I323 to the action of the spring 5326, rocking the bell crank I 3I 6 counter-clockwise to raise the feeler I3I5 to feel for a slip in the machine. If no slip is present on the sliptable I243, the slip feeler I3I5 is permitted to rise, and therefore the spring I329 moves the link I323 to the right (Fig. 16) to cause the finger I326 to follow the flange I321. Counter-clockwise movement of the cam follower arm I339 to its fullest extent moves the flange I321 beyond a surface I343 (Fig. 14), whereupon the flange 532i drops behind the surface I343. This movement is permitted by a notch I344 in the arm i326 and is effected by a spring I 345 stretched between a stud on the pawl I323 and the cam arm 5335. When the flange I321 is in the notch I344 and behind the surface I343 of the segment i349, and the cam arm I339 is restored to its home position by the cam I 332, the pawl I 328 rocks the segment I349 clockwise, thus rocking the arm I 331 and the shaft I 216 counter-clockwise (Figs. 14, 15, and 16). Counter-clockwise movement of the shaft I213 moves the segment I335 (Fig. 15) beneath the fiange I336 to pre vent downward movement of the link I292, which prevents operation of the printing hammer.

If a slip is present on the slip table I243, then, when the slip feeler I3I5 begins to rise, the feeler is arrested by coming into contact with the inserted slip, and therefore the feeler I 3i5, the bell crank iZ-ZIS, the shaft I3I9, the link 5323, and the arm I324 are arrested. Therefore, when the cam arm I339 is rocked counter-clockwise, the flange 5321 of the pawl I328 rides on the periphery I342 of the segment I 324, therefore the flange I 32'? cannot drop into the path of the surface I353 of the segment I343. If the flange I321 cannot drop into the path of the surface I 343, the fiange I321 is held out of the of the surface i333 of the segment I343, and therefore, upon return movement of the cam arm the flange of the pawl 5323 does not rock the segment i343, which results in the shaft I216 being held stationary, and the segment I335 (Fig. 3.5) is held out of the path of the flange I336 of the lint: i232. Therefore, when a slip is on the slip table 5263, the link i232 is free to operate to control the operation of the printing hammer, in a manner described hereinbefore.

Slip feed tension rollers In order to space the printed data on the deposit slips (Fig. 22) so that the two impressions can be made, one for each copy thereof, mechanism is provided for feeding the deposit slip between the two impressions. The feed rollers are normally separated so that the deposit slip, or the tellers cash ticket, can be easily inserted into the machine. Immediately after the machine begins to operate, the feed rollers are brought together to grip the inserted slip, not only during the feeding movements but also at the time the printing takes place, to maintain the inserted slip in proper position.

The mechanism for controlling the tension rollers is shown in Fig. 29. Two upper feed rollers I355 are rotatably mounted on the stationary shaft 204. Two tension rollers I356 (Figs. 28 and 29) are provided, which are movable to come into contact with the stationary rollers I355 immediately the machine begins to operate. The tension feed rollers I356 are coupled together by a sleeve I 351 and are rotatably mounted on a. shaft I358 carried by two arms I359 securely mounted on the beforesaid shaft I3I1. Also secured on the shaft I3I1 is an arm I360 (Fig. 29), which is connected to a cam arm I36I by a link I362. The cam arm I36I is provided with an anti-friction roller I 363, held in engagement with a cam I364, secured to the hub of the beforementioned cam I332, whereby the cam is secured to the printer cam shaft I213. A spring I365, connected at one end to one of the arms I359 and at the other end to a stud on the frame I3I, normally maintains the roller I363 in contact with the periphery of the cam I364. When the cam I364 is in its home position, as shown in Fig. 29, the tension roller I356 is in its lower position and out of contact with the stationary feed rollers I355, thus clearing the opening for inserting the slip into proper position for receiving the impression.

Immediately upon the beginning of the operation of the machine, the cam I364 rotates counter-clockwise, thus permitting the spring I365 to rock the cam arm I36I clockwise, which movement, through the link I362 and the arm I369, transmits similar clockwise rotation to the shaft I3I1, thus raising the roller-supporting arms I359 to bring the tension rollers I356 into contact with the inserted slip and pressing it against the stationary feed rollers I355. Near the end of the machine operation, after all impressions have been made, the cam I364 rocks the cam arm I36I counter-clockwise to restore the tension feed rollers I356 to their normal positions, shown in Fig. 29.

Slip feed mechanism After the tension rollers I356 are rocked to their upper positions by the cam I364 and the connecting mechanism therebetween, and after the first impression has been made upon the deposit slip, the tension rollers I356 are given a counter-clockwise rotation to feed the slip an extent suflicient to present the next printing line to the printing position.

Means, to be presently described, is provided in the machine and can be manually set to vary the extent of the feeding of the insertable slip in accordance with a particular form being used in the machine. This variable feed provides a convenient means to adapt the machine to whatever form a bank or other business institution may want to adopt.

The mechanism for feeding the insertable slip is normally ineffective to rotate the feed rollers I356 but is controlled from the keys of the first and second transaction banks, so that the feed mechanism will be operative during the machine operation in which a printinr. takes place. If the printing mechanism is automatically thrown off in the manner described hereinbefore, the feed mechanism is also thrown off On the other hand, if the printing mechanism is thrown on to effect a print, the feed mechanism also is thrown on, so that the slip will be fed to space the two printed records.

Secured to one end of the shaft I359 (Figs. 26 and 28) is a pinion I310 to mesh with a rack I31 I. The rack I31I is connected to a lever I312 by a link I313. The lever I3 2 is pivoted on a stud I314 mounted on the side frame IBI and is provided with a stud I315 at its lower end, normally held a ainst the end of a pusher slide I316 by a spring I311. The pusher slide I315 is slotted to slide on a guide stud I318 mounted on the side frame I8I. Pivoted at the rear end of the pusher slide I316 is a cam arm I319 pivoted on the beforementioned shaft I325. The cam arm I319 is provided with an anti-friction roller I380, held in engagement with the periphery of a cam I38I, secured to the printer cam shaft I213, by the spring I311.

The pusher slide is provided with a stud I382, which is normallv engaged by a lateral extension I383 of a vertically-movable pitman I394. The pitman I384 is controlled in its movements by control discs differentially set under control of the transaction bank of kevs, in a manner to be described hereinafter, so that, when no feed is required, the extension I393 remains in the path of the stud I362, and, when a feed is required, the vertical extension I383 is lowered out of the path of the stud I382.

If the extension I383 is out of the path of the stud I382 and the printer cam shaft I213 rotates counter-clockwise, the spring I311, acting through the lever I312, the stud I315, and the pusher slide I316. causes the roller I380 to follow the contour of the cam I38I and thereby rock the cam arm I3 9 counter-clockwise. Counterclockwise movement of the cam arm I319 moves the pusher slide I316 to the right (Fig. 26), and the sprin I311 moves the link I313 to the left, thus movin the rack I31I to the left to rotate the pinion I310 clockwise. Clockwise movement of the pinion I310 rotates the shaft I358 likewise. However, at this time, the shaft I358 is uncoupled from the feed rollers I355. and therefore the feed rollers are not rotated. Upon further rotation of the cam I38I, its contour rocks the cam arm I319 clockwise, thus moving the pusher slide I318 to the left (Fig. 26), and, through the lever I312, moves the link I313 and the rack I 31 I to the ri ht, thus rotating the pinion I310 and the shaft I358 counter-clockwise. During the counter-clockwise rotation of the shaft I359. a clutch between the shaft I358 and the feed rollers I356 is effective, as will be described hereinafter, to rotate the feed rollers I356 to space the inserted slip to receive the second impression.

The extent of feeding movement to be iven to the inserted slip is controlled by a plate I385, rotatably mounted on the shaft I216. The plate I385 is provided with a plurality of steps I306 of varying distances from its pivot point. Any of the steps I386 may be brought into the path of the stud I382 by removing a screw I301, which is screwed into the side frame I8I of the machine.

Upon removal of the screw I361, the plate I385 can be manually positioned in any of its disclosed positions, and, upon reinsertion of the screw I361, the plate I385 is held in the desired position. When the pusher slide I316 is released for movement to the right (Fig. 26) by the contour of the cam I33I, the stud I382 thereon comes into contact with the step I386 in its path. The movement given to the slide I316 is determined by the space between the stud I 382 and the selected step I386. In the machine used to illustrate the present invention, the steps I386 are so arranged that the distance between prints on the insertable slip can be varied from .6" to 2 in steps of .2". These dimensions are illustrative only, and any desired dimensions may be used in building the machine,

The clutch arrangement between the shaft I358 and the feed rollers I356 is illustrated in enlarged scale in Fig. 30. Secured to the shaft I358 is a disc I390 (see also 28), having a divided cylindrical portion I39I, which projects inwardly into the inner diameter of a ratchet ring I 392. Slidably mounted in the runways provided in the cylindrical portion I39I are a pair of one-way drive pawls I393, which are forced into teeth of a ratchet ring by a spring I394. The spring I394 passes through an opening drilled through the shaft I358, so that the pawls I393 may be forced outwardly to engage the inner ratchet teeth of the ring I392. The ratchet ring I392 is secured to one of the feed rollers I356 by two studs I395.

When the shaft I356 receives its clockwise rotation at the beginning of the operation of the feed mechanism, the feed pawls I393, camming against the ratchet teeth, are both moved inwardly to disconnect the driving connection between the shaft I350 and the feed roller I356. A brake mechanism, described hereinafter, prevents accidental rotation of the feed rollers I356 during this operation. Upon the counter-clockwise rotation of the shaft I358, the pawls I393 form a driving connection between the cylinder I39I and the ratchet ring I392, thus rotating the feed rollers I356 counter-clockwise to feed the inserted slip from one printing position to the other.

The clutch mechanism shown in Fig. 30 is provided in only one of the feed rollers I356. However, inasmuch as the two feed rollers are connected together by the sleeve I351 in the manner hereinbefore described, both feed rollers partake of the rotating movement.

The brake mechanism for the feed roller I366, mentioned hereinbefore, consists of a springactuated brake I396 (Fig. 26), which has a formed end normally held in engagement with one feed roller I356 by a spring I391. The brake member I396 is pivoted on a stud I398 on an extension of one of the tension arms I359.

If, when the shaft I353 receives its initial or clockwise rotation, the feed roller I35 should tend to be moved clockwise by the clutch pawls I393, the coaction between the periphery of the feed roller I356 and the formed end of the brake member I396 is such that the roller I356 is wedged against the brake member I393, and rotation thereof is prevented. The reason for this wedging action is that the point of contact of the formed member of the brake member I393 is below center of the line drawn between the pivot point of the brake member I336 and the shaft I358. Clockwise rotation of the feed roller I355, therefore, has a tendency to rock the brake member I395 counter-clockwise, thus causing a wedging action, which prevents such rotation of the feed roller !355.

As disclosed in 28, each of the feed rollers 93% is provided with a surface of resilient inaterial such as rubber, to effect a better gripping action therebetween and the stationary rollers i Means is also provided on the shaft 358 to prevent any excess rotation of the feed rollers 5356 at the end. of a feeding operation. This lock includes the cam member Milli (Fig. 27) secured on the end of the shaft I358. Normallythat is, when the machine is at restthe cam i495 lies in the path of a pawl MEI connected to a second pawl M92 by a stud I593 and holds the pawl i in contact with a ratchet wheel E ite coupled to the right-hand feed roller I35E. As long as the cam I lcii blocks movement of the pawl M ll, the pawl is locked in engagement with the teeth of the ratchet wheel I 464, thus preventing any rotation of the feed rollers i356. However, upon initial clockwise rotation of the shaft after the feed rollers have been raised into feeding position, the cam Milli moves away from the pawl Mill, thus permitting a spring E 365, connected to the pawl I 152 at one end and to a stud on one of the arms I359 at its other end, to withdraw the nose of the pawl M32 from engagement with the ratchet wheel Mil i, thus freeing the rollers I355 to the action of the feeding mechanism hereinbefore described.

Automatic slip feed control disc The position of the pitman I384 and its lateral extension 333 is automatically controlled by notched discs Hill and HlII (Figs. 24 and 26). The disc Mill is provided with internal teeth rotatably mounted on a disc MI carried by the shaft 332. The internal teeth or" the disc i558 are in engagement with a pinion Milt mounted on the beforementioned shaft 753, which is adjusted under control of the second transaction bank in the manner hereinbefore described.

The disc l iii (Fig. 26) is provided with internal teeth which rotate on a disc I 4| 4, rotatably mounted on the shaft 632. The internal teeth of the disc l lli mesh with a pinion HHS carried by the shaft i i-3, which is clifierentially positioned under control of the first transaction bank in a manner hereinbefore described.

A feeling finger l liii is provided to engage are periphery of, or a notch in, the disc I lil, and eeling finger i lil' is provided to engage the 'iphery of, or a notch in, the disc MI I. The fmger is integral with an adjustable block I4I8 rotatably mounted on a stud IQIQ carried by a slide the forward end of which slide has the finger i lil formed thereon. A spring plate 5 32i, carried by studs 6.22 on the slidelflil, provides means for holding the block I-iIS in its adjusted position. The slide I 528 is slotted to slide on the beiorementioned stud I288. The beforementioned spring I see having one end connected to the stud 62% and the other end to the pivot stud for the slide H320, said pivot stud provides a connection between the slide M29 and the beforeinentioned yolze H52 3, rotatably mounted on the shaft 529%. The yoke I423 has one arm M2 5 projecting to the right (Fig. 26), carrying the stud M25, normally held against the beiorementioned arm I296 by the spring I299. The yoke M23 is provided with a second arm I 426, to which the upper end of the beforementioned pitman I384 is pivoted.

When the cam IZiis rocks clockwise, as described hereinbefore, to permit the arm I296 to move clockwise, the stud M25 and the yoke I l23 are released to the action of the spring iiilil, whereupon'the slide 5 42!] tends to move leftwardly (Fig. 26) to bring the feeling fingers hilt and MIT into contact with the peripheries or notches of the discs Hit and NIH. If the Deposit key has been depressed prior to the operation of the machine, the second transaction bank difierential, acting through the square shaft 753 and the pinion I i-i3, adjusts the disc I liil to present either the notch s or the notch 8 (Fig. 24) into the path of the finger ms. During a deposit transaction entry operation, no key is depressed in the first transaction bank, and therefore a notch I9 is in the path of the finger Hill. During such an operation, both fingers was and M l l are permitted to enter notches in their associated discs I M 8 and Hi: I, and therefore the yoke M523 is rocked clockwise to lower the pitman I384 and thereby to remove the lateral extension I3 from the path of the stud I3tl'i, which, as described hereinbeiore, results in a feeding movement of the feed rollers I356.

If any of the keys in the second transaction bank other than a Deposit key is depressed, then an unnotched portion of the disc IilItl is in the path of the finger I4I5. During this operation, when the yoke I423 is released by the cam I296, the slide M28 is immediately arrested due to the finger H6 coming into contact with the periphery of the disc MIG. During this operation, the yoke I423 is not permitted to move, and therefore the pitman I 38; remains in the position shown in Fig. 26, wherein the lateral er.- tension I383 remains in the path of the stud I382. During this operation of the machine, the pusher slide I318 cannot move, and therefore the feed rollers I355 are not rotated.

If it is desired to change the control of the feed mechanism for an inserted slip for any reason, the block I4I8 can be rotated on its stud Hi9 manually to move a feeler Mill thereon into effective position to coact with a notched i 323 (Fig. 25), and simultaneously the finger I553 is removed from coasting position with the notched disc MIG. With this setting, the disc being notched differently from the disc i iiil, will earn trol the effectiveness of the slip feeding mechanism in accordance with any difjerent system. The notching shown in Fig. 25 is illustrative only and can be arranged in any desired manner.

As illustrated, the disc Idiiil is adjusted under control of the second transaction bank in the same manner as described for the adjustment of the notched disc I 4H3.

While the form of mechanism shown and described herein is admirably adapted to fulfill the objects primarily stated, it is to be understood that it is not intended to confine the invention to the one form or embodiment disclosed herein, for it is susceptible of embodiment in various other forms.

What is claimed is:

1. In a machine of the class described, in combination with type carriers, printing means to take impressions from the type carriers onto rec-0rd material, power-operated means to actuate the printing means, said power-operated means including a toggle connection which may be operated to actuate the printing means to take one or two impressions on the record ma- 

